Search
Menu
Opto Diode Corp. - Opto Diode 10-24 LB

Stretchable Semiconductors Detect Ultralow Light

Facebook X LinkedIn Email
A stretchable semiconductor material developed by researchers at Georgia Institute of Technology (Georgia Tech) is able to act like a second layer of skin and detect ultralow levels of light. The researchers believe that their soft flexible photodetectors could enhance the utility of medical wearable sensors and implantable devices and support additional applications.

The work stems from a multiyear collaboration between Georgia Tech researchers from mechanical and computing engineering labs. The current development of a new level of “stretchability” for a photodetector is made from a synthetic polymer and an elastomer that absorbs light to produce an electrical current. The device is up to 200% more stretchable than its original dimension without significant loss to its electrical current.
Three engineering labs at Georgia Tech collaborated to demonstrate a new level of stretchability of a photodetector. Pictured above is first author Youngrak Park (right) with the lab leads (from left) Bernard Kippelen, Samuel Graham, and Olivier Pierron. Courtesy of Ben Wright, Georgia Institute of Technology.
Three engineering labs at Georgia Tech collaborated to demonstrate a new level of ‘stretchability’ of a photodetector. Pictured is first author Youngrak Park (right) with the lab leads (from left) Bernard Kippelen, Samuel Graham, and Olivier Pierron. Courtesy of Ben Wright, Georgia Tech. 
Since conventional flexible semiconductors break under a few percentages of strain, the work offers a significant improvement, according to Oliver Pierron, a professor in the George W. Woodruff School of Mechanical Engineering.

“Think of a rubber band or something that’s soft and stretchable like human skin, yet has similar electrical semiconducting properties of solid or rigid semiconductors,” said Canek Fuentes-Hernandez, a co-principal investigator formerly in the School of Electrical and Computer Engineering and now an associate professor at Northeastern University. “We’ve shown that you can build ‘stretchability’ into semiconductors that retains the electrical performance needed to detect light levels that are around hundred million times fainter than produced by a light bulb used for indoor illumination.”

Excelitas Technologies Corp. - X-Cite Vitae  MR 11/24

Determining the proper balance of chemical compounds to produce a soft material capable of generating and conducting electricity when exposed to light was the result of two and a half years of work by study first author Youngrak Park.
Kyungjin Kim, now a professor at the University of Connecticut, demonstrating a stretched elastomer film. Courtesy of Kyungjin Kim.
Kyungjin Kim, a professor at the University of Connecticut, demonstrating a stretched elastomer film. Courtesy of Kyungjin Kim.

Proving the material’s “stretchability” was another matter, given that a single layer of the material is 1000× thinner than a human hair. Park provided samples to Kyungjin Kim, at the time a Ph.D. student and now an assistant professor at the University of Connecticut, to test durability. A sample with a thickness of 500 nm eventually validated the work.

“It was still super thin. Under dry conditions, it would just crumble. We had to use a water reservoir to keep its shape,” Kim said.  

Though the material has been integrated into a photodetector and tested for electrical functionality, more testing and optimization is needed to show the material’s “stretchability” under multimodal loads and its shelf stability, the researchers said.

“What’s exciting is what these materials and the devices will enable us to develop — namely, the concept of intelligence systems,” said Samuel Graham, former chair of the Woodruff School of Mechanical Engineering and now dean of engineering at the University of Maryland. “You have functional surfaces that combine sensors that monitor all kinds of physical properties.” 

The research was published in Science Advances (www.doi.org/10.1126/sciadv.abj6565).


Published: December 2021
Glossary
photodetector
A photodetector, also known as a photosensor or photodiode, is a device that detects and converts light into an electrical signal. Photodetectors are widely used in various applications, ranging from simple light sensing to more complex tasks such as imaging and communication. Key features and principles of photodetectors include: Light sensing: The primary function of a photodetector is to sense or detect light. When photons (particles of light) strike the active area of the photodetector,...
substrate
A substrate refers to a material or surface upon which another material or process is applied or deposited. In various fields, such as electronics, biology, chemistry, and manufacturing, the term "substrate" is used with specific contexts, but the fundamental definition remains consistent: it is the underlying material or surface that provides a foundation for subsequent processes or applications. Here are some examples of how a substrate is used in different fields: Electronics: In...
Research & TechnologyMaterialssemiconductorsphotodetectorSensors & Detectorslight detectionstretchableskinflexiblesubstrateelectronicBiophotonicshealth monitorwearableGeorgia Institute of TechnologyAmericas

We use cookies to improve user experience and analyze our website traffic as stated in our Privacy Policy. By using this website, you agree to the use of cookies unless you have disabled them.